JP2004094017A - Liquid crystal display - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid crystal display having a driving method for relieving burning due to long time impression of DC voltage components to a liquid crystal and by which a flicker is not recognized. <P>SOLUTION: Voltage of -Va is impressed in a field of 2n-1, voltage of -Vc is impressed in a 2n field and voltage of +Va is impressed in a 2n+1 field to pixels in a first column of a k-1 line. Furthermore, voltage of +Va is impressed in a 2n+m-1 field after m fields, voltage of +Vc is impressed in an 2n+m field, voltage of -Va is impressed in an 2n+m+1 field and voltage of +Va is impressed in an 2n+m+2 field, respectively. Period of an inputted video signal and period of reverse voltage polarity of the inputted video signal are driven so that they are alternately inverted by every period (S period) longer than one field unit and the voltage of -Vc is impressed in the 2n field and the voltage of +Vc is impressed in the 2n+m after the S period to the pixels in the first column of the k-1 line to which the DC voltage components are generated in accordance with inversion of the periods. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a liquid crystal display device, and more particularly to a liquid crystal display device having a driving method capable of preventing image sticking and reducing flicker.
[0002]
[Prior art]
Display using an interlace video signal, which is performed in a conventional matrix type liquid crystal display device, will be described. FIG. 5A is a schematic view of a display according to a conventional matrix type liquid crystal display device. In this schematic diagram, pixels are illustrated in a matrix of 6 rows and 8 columns from k−2 rows to k + 3. In the figure, white circles, black circles, white squares, and black squares indicate pixels, and a white circle is applied with a voltage of + Va, a black circle is applied with -Va, a white square is applied with a voltage of + Vb, and a black square is applied with a voltage of -Vb. I have.
[0003]
The driving method of the matrix type liquid crystal display device is an AC driving method, and the AC driving method includes a frame inversion, a line inversion, and a dot inversion. In FIG. 5, a description will be given of a dot inversion method. The dot inversion method is a driving method in which the polarity between adjacent dots (pixels) is inverted so that the polarity differs in each field. For example, focusing on the pixel in the (k-1) -th row and the first column, a voltage of -Va is applied in the 2n-1 field, a voltage of + Va is applied in the 2n field, and a voltage of -Va is applied in the 2n + 1 field.
[0004]
FIG. 5B shows a voltage waveform applied to the pixel in the (k-1) -th row and the first column. This waveform is to prevent a DC voltage from being applied to the liquid crystal for a long time to cause polarization inside the liquid crystal and to cause display defects such as burn-in. That is, the voltage + Va is applied in the 2n-2 and 2n fields of the even field, and the voltage -Va is applied in the 2n-1 and 2n + 1 fields of the odd field. Therefore, the voltages cancel each other out in the even field and the odd field, and there is no DC voltage component in the pixel in the (k-1) -th row and the first column.
[0005]
However, the interlace video signal input to the matrix type liquid crystal display device is not always the same video signal in the even field and the odd field. In other words, not only when the same voltage having different polarities is applied to the even field and the odd field as in the pixel in the (k-1) -th row and the first column, voltages having different magnitudes may be applied. For example, focusing on the pixel at k rows and 1 column shown in FIG. 5A, a voltage of + Va is applied to the odd field and a voltage of -Vb is applied to the even field.
[0006]
In this case, FIG. 5C shows a voltage waveform applied to the pixel in the k-th row and the first column. In this waveform, the voltage -Vb is applied in the 2n-2 and 2n fields of the even field, and the voltage + Va is applied in the 2n-1 and 2n + 1 fields of the odd field. Therefore, the voltages do not cancel each other in the even field and the odd field, and a DC voltage component remains in the pixels in k rows and 1 column. The DC voltage component at this time is (Va-Vb) / 2. If this state continues for a long time, display defects such as burn-in will occur.
[0007]
Therefore, as a driving method for preventing display defects such as burn-in due to the remaining DC voltage component, there are the following driving methods. FIG. 6A is a schematic view of a display according to a matrix type liquid crystal display device. In the schematic diagram of FIG. 6A, pixels are illustrated in a matrix of 6 rows and 8 columns from k−2 rows to k + 3 as in FIG. 5A. In the figure, white circles, black circles, white squares, and black squares indicate pixels, and a white circle is applied with a voltage of + Va, a black circle is applied with -Va, a white square is applied with a voltage of + Vb, and a black square is applied with a voltage of -Vb. I have.
[0008]
Focusing on the pixel at k rows and 1 column, a voltage of + Va is applied in the 2n-1 field, a voltage of + Vb in the 2n field, and a voltage of -Va in the 2n + 1 field. Further, a voltage of -Va is applied in the 2n + m-1 field after m fields, -Vb in the 2n + m field, + Va in the 2n + m + 1 field, and -Vb in the 2n + m + 2 field. This is shown in FIG. 6C as a voltage waveform applied to the pixels in k rows and 1 column.
[0009]
In this waveform, the voltage polarities applied to the even / odd fields before the 2n-1 field and the voltage polarities applied to the even / odd fields from the 2n field to the 2n + m-1 field are inverted. In other words, in the driving method shown in FIG. 6, the period of the input video signal and the period of the reverse voltage polarity of the input video signal are alternately changed every cycle longer than one field unit (m fields in FIG. 6). This is a driving method that reverses. As a result, as shown in FIG. 6C, a DC voltage component of + (Va−Vb) / 2 occurs before the 2n−1 field due to the difference between the voltages applied to the even field and the odd field. Up to the 2n + m-1 fields, a DC voltage component of-(Va-Vb) / 2 occurs due to the difference between the voltages applied to the even and odd fields.
[0010]
Therefore, when driving is performed by this driving method for a long period of time, a DC voltage component of + (Va−Vb) / 2 and a DC voltage component of − (Va−Vb) / 2 appear for every m fields, and the DC voltage components are mutually reduced. They will negate each other. Therefore, the DC voltage component does not remain in the pixel at k rows and 1 column, and the problem of display failure such as burn-in can be solved.
[0011]
Note that, even when focusing on the pixel in the k-1 row and the 1 column, a voltage of -Va is applied in the 2n-1 field, -Va in the 2n field, and + Va in the 2n + 1 field. Further, + Va is applied in the 2n + m-1 field after m fields, + Va in the 2n + m field, -Va in the 2n + m + 1 field, and + Va in the 2n + m + 2 field. This is shown in FIG. 6B as a voltage waveform applied to the pixels in k rows and 1 column.
[0012]
Even in the pixel of the (k-1) -th row and the first column, the period of the input video signal and the period of the reverse voltage polarity of the input video signal are alternately changed every cycle longer than one field unit (m fields in FIG. 6). 6B, a DC voltage component of −Va / 2 occurs in the 2n field, and a DC voltage component of + Va / 2 occurs in the 2n + m field, as shown in FIG. 6B. Similarly to the pixel in the k-th row and the first column, by driving this driving method for a long period, a DC voltage component of + Va / 2 and a DC voltage component of -Va / 2 appear for every m fields, and the DC voltage The ingredients will negate each other. Therefore, no DC voltage component remains in the pixels in the (k-1) -th row and the first column. The driving method shown in FIG.
[0013]
By performing the driving method shown in FIG. 6, it is possible to cancel out DC voltage components applied to the pixels and eliminate the problem of display failure such as burn-in. However, the driving method is such that the period of the input video signal and the period of the reverse voltage polarity of the input video signal are alternately inverted every cycle longer than one field unit (m fields in FIG. 6). Therefore, as shown in FIG. 6B, a DC voltage component having a magnitude of Va / 2 appears every m fields. Therefore, this DC voltage component is superimposed on the voltage applied to the pixel, causing a luminance difference and causing flicker on the screen of the liquid crystal display device. Generally, the magnitude of the DC voltage component is not directly superimposed on the video signal, but the intensity of flicker depends on the magnitude of the DC voltage component.
[0014]
Therefore, as a driving method for reducing flicker, there is a method of synchronizing a switch of a liquid crystal light source with a liquid crystal drive signal and changing the luminance of the liquid crystal light source in accordance with the timing at which flicker is seen on the screen. With this driving method, it is possible to reduce the flicker to a level below the level recognized by human eyes. This driving method is described in detail in Patent Document 2.
[0015]
[Patent Document 1] Japanese Patent No. 2577796
[Patent Document 2] Japanese Patent Application Laid-Open No. 2000-214437
[0016]
[Problems to be solved by the invention]
However, according to the driving method disclosed in Patent Document 2, since the luminance of the light source in the liquid crystal display device is changed, only the entire screen can be changed uniformly. On the other hand, flicker does not occur uniformly on the entire screen, but varies depending on the voltage (for example, + Va) applied to the pixel. Further, since the intensity of flicker depends on the magnitude of the DC voltage component applied to the pixel, if the DC voltage component is partially different, the intensity of flicker also differs within the screen.
[0017]
Therefore, in the case where video signals having different luminances are input in one screen, or in the case of a moving image in which the video signals are sequentially updated, even if the driving method disclosed in Patent Document 2 is used, the flicker generated in the screen may be reduced. I can't handle everything. Therefore, even with the driving method disclosed in Patent Document 2, flicker may be recognized by human eyes.
[0018]
SUMMARY OF THE INVENTION It is an object of the present invention to provide a liquid crystal display device having a driving method that reduces burn-in caused by applying a DC voltage component to a liquid crystal for a long time and does not recognize flicker.
[0019]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a liquid crystal display device in which pixels are arranged in a matrix and video signals input in odd fields and even fields are interlacedly driven, wherein the odd fields and the even fields are different. Means for inverting the voltage polarity of the input video signal, and alternately inverting the period of the input video signal and the period of the reverse voltage polarity of the input video signal for each predetermined period longer than one field Means for generating corrected video data to be supplied to the pixels by changing the video signal and belonging to the first field of the timing when the period of the input video signal and the period of the reverse voltage polarity of the input video signal are inverted. Video signal control means.
[0020]
According to a second aspect of the present invention, there is provided the liquid crystal display device according to the first aspect, wherein the video signal control unit generates corrected video data by multiplying the video signal by a predetermined coefficient.
[0021]
According to a third aspect of the present invention, there is provided the liquid crystal display device according to the second aspect, wherein the video signal control means changes a predetermined coefficient to be applied to the video signal according to the luminance of the video signal.
[0022]
According to a fourth aspect of the present invention, there is provided the liquid crystal display device according to the first aspect, wherein the video signal control means generates corrected video data by adding a predetermined value to the video signal.
[0023]
According to a fifth aspect of the present invention, there is provided the liquid crystal display device according to the fourth aspect, wherein the video signal control means changes a predetermined value to be added to the video signal according to the magnitude of the luminance of the video signal.
[0024]
A solution according to claim 6 of the present invention is the liquid crystal display device according to claim 1, wherein the video signal control means refers to a predetermined look-up table and corrects the corrected video data corresponding to the video signal. Generate
[0025]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be specifically described with reference to the drawings showing the embodiments.
[0026]
(Embodiment 1)
FIG. 1 shows a configuration diagram of a matrix type liquid crystal display device 1 according to the present embodiment. In FIG. 1, a video signal output from a PC or the like is input to a basic circuit 2. The basic circuit 2 performs necessary operations such as image quality correction of a video signal, generation and scaling of a module control signal, as in other liquid crystal display devices. The CPU 3 controls the basic circuit 2 and the timing generation circuit 4, and controls the driving of the liquid crystal display device in the present embodiment.
[0027]
Next, the timing generation circuit 4 generates a timing signal that allows the AC drive control circuit 6 to drive the voltage polarity in synchronization with the vertical synchronization signal V that drives the liquid crystal panel 5. The AC drive control circuit 6 generates a signal for controlling the voltage polarity of the liquid crystal panel 5. In the present embodiment, the voltage polarity is controlled by changing the pulse width of the vertical synchronization signal V. Note that the pulse width is specified by the CPU 3.
[0028]
Next, the image correction circuit 7 changes the video signal to cancel the flicker and generates corrected video data in accordance with the timing at which the AC drive control circuit 6 controls the voltage polarity. The generation of the corrected video data is controlled by the CPU 3. Video signals that do not need to be changed are converted to video data. The liquid crystal panel 5 includes a display panel, a driver for inverting a voltage polarity applied to a pixel for each field of an odd field and an even field, and a video signal of an input video signal for each cycle longer than one field. A driving circuit is provided such that the period and the period of the reverse voltage polarity of the input video signal are alternately inverted. Then, the liquid crystal panel 5 displays on the display panel in accordance with the video data and the corrected video data output from the image correction circuit 7, the polarity control signal output from the AC drive control circuit 6, and the timing signal output from the basic circuit 2. To display the video.
[0029]
FIG. 2A is a schematic view of a display of the matrix type liquid crystal display device according to the present embodiment. In the schematic diagram of FIG. 2A, pixels are illustrated in a matrix of 6 rows and 8 columns from k−2 to k + 3. Also, white circles, black circles, white squares, black squares, white triangles, black triangles, white rhombuses, and black rhombuses in the figure indicate pixels, with + Va for white circles, -Va for black circles, + Vb for white squares, and black. A voltage of -Vb is applied to the square, a voltage of + Vc is applied to the open triangle, a voltage of -Vc is applied to the open triangle, a voltage of + Vd is applied to the open diamond, and a voltage -Vd is applied to the open diamond.
[0030]
Paying attention to the pixel at k rows and 1 column in FIG. 2A, + Va is applied in the 2n-1 field, + Vd is applied in the 2n field, and -Va is applied in the 2n + 1 field. Further, a voltage of -Va is applied in the 2n + m-1 field after m fields, -Vd in the 2n + m field, + Va in the 2n + m + 1 field, and -Vb in the 2n + m + 2 field. FIG. 2C shows this as a voltage waveform.
[0031]
In this waveform, a DC voltage component of + (Va−Vb) / 2 occurs in the even-numbered and odd-numbered fields before 2n−1 field. Therefore, if this DC voltage component exists in the pixels in k rows and 1 column for a long time, burn-in occurs. Therefore, in the driving method of the liquid crystal display device according to the present embodiment, in the S period from the 2n field to the 2n + m-1 field, the reverse voltage polarity of the video signal applied to the even and odd fields before the 2n-1 field is applied. Have been. Therefore, a DC voltage component of-(Va-Vb) / 2 is generated from the 2n field to the 2n + m-1 field, and the DC voltage component of + (Va-Vb) / 2 generated before the 2n-1 field is canceled. become. Here, although + Vd is applied in the 2n field and -Vd is applied in the 2n + m field, the DC voltage component is approximately the above value because one field is much shorter than the S period.
[0032]
That is, in the driving method shown in FIG. 2C, the period of the input video signal and the period of the reverse voltage polarity of the input video signal are alternately changed for each period (S period) longer than one field unit. This is a driving method that reverses. As a result, a period of the DC voltage component of + (Va−Vb) / 2 and a period of the DC voltage component of − (Va−Vb) / 2 appear for each S period, and the DC voltage components cancel each other out and k row 1 Reduce the burn-in of pixels in a column.
[0033]
Note that the S period is longer than one field unit, but shorter than the period in which an afterimage remains in a pixel. Further, the S period is a period of substantially m fields, but does not have to be strictly equal. This is because, when the polarity is controlled in an approximate time near the m-field, the DC voltage components are almost canceled out in a long time, and burn-in can be reduced.
[0034]
The voltage polarity is controlled by supplying an H / L control signal from the outside to the liquid crystal panel 5, or controlled by the relationship between the vertical synchronization signal V of the AC drive control circuit 6 and the enable signal En. There are things to do. In the present embodiment, control is performed by the relationship between the width of the vertical synchronization signal V and the enable signal En (the timing from the beginning of the vertical synchronization signal to the beginning of the enable signal is always constant), that is, the width of the vertical synchronization signal V is set to 1 The polarity is inverted by increasing or decreasing the horizontal (H).
[0035]
Next, attention is paid to the pixel in the (k-1) -th row and the first column in FIG. In FIG. 6, the period of the input video signal and the period of the reverse voltage polarity of the input video signal are alternately inverted for each period longer than one field unit (m fields in FIG. 6), thereby increasing the size. A DC voltage component of Va / 2 appears every S period (m fields). For this reason, this DC voltage component is superimposed on the voltage applied to the pixels in the 2n field, changing the luminance of the pixels and causing flicker on the screen of the liquid crystal display device.
[0036]
In the present embodiment, it is necessary to consider that the voltage of -Va should be applied to the pixel of the (k-1) -th row and the first column in the 2n field of FIG. A voltage of Vc is applied. That is, in the pixel on the (k-1) -th row and the first column in FIG. 2A, a voltage of -Va is applied in the 2n-1 field, -Vc in the 2n field, and + Va in the 2n + 1 field. Further, + Va is applied in the 2n + m-1 field after m fields, + Vc in the 2n + m field, -Va in the 2n + m + 1 field, and + Va in the 2n + m + 2 field. FIG. 2B shows this as a voltage waveform.
[0037]
In the driving method according to the present embodiment, the period of the input video signal and the period of the reverse voltage polarity of the input video signal are alternately inverted every cycle (S period) longer than one field unit. In consideration of a DC voltage component generated by driving, a voltage of -Vc is applied in the 2n field and a voltage of + Vc is applied in the 2n + m field after the S period with respect to the pixel in the (k-1) -th row and the first column. This makes it possible to reduce flicker due to the DC voltage component to be superimposed as compared with the case where the voltages of -Va and + Va are applied to the 2n field and the 2n + m field.
[0038]
Here, the voltage applied to the pixel in the (k-1) -th row and the first column in the 2n field is described. First, a video signal for applying a voltage of −Va from the liquid crystal panel 5 is input to the basic circuit 2, and the video signal is sent to the image correction circuit 7. Under the control of the CPU 3, in the image correction circuit 7, the video signal is multiplied by a correction coefficient α to generate corrected video data. The corrected video data is input to the liquid crystal panel 5, and a voltage of -Vc is applied to the pixels in the (k-1) -th row and the first column. If the amount of change in luminance per unit luminance due to the DC voltage component occurring in the 2n field is Dc, the correction coefficient α is 1-Dc. For example, when the luminance change amount Dc is 0.1 in a video signal having a luminance of 50% (expressed as a voltage applied to the pixel as + Va), the correction coefficient α is calculated from (1-0.1). 0.9, and the corrected video data has a luminance of 45% from (50% × 0.9). When this 45% luminance is represented by a voltage applied to the pixel, it is + Vc.
[0039]
Similarly, corrected video data is generated from a video signal in all pixels and all fields where a DC voltage component occurs. For example, a voltage of -Vd in the 2n field and a voltage of + Vd in the 2n + m field are applied to the pixels in the k + 3 rows and 1 column. In general, the magnitude of the DC voltage component depends on the magnitude of the applied voltage, and the intensity of flicker depends on the magnitude of the DC voltage component. Therefore, the flicker intensity of the pixel in the (k + 3) row and the first column is smaller than the flicker intensity of the pixel in the (k-1) row and the first column because of the relationship (+ Va)> (+ Vb).
[0040]
FIG. 3 shows a timing chart of video data according to the present embodiment. Where D _2n Is video data in 2n fields. In the present embodiment, the corrected image is added to the first field 2n field and the 2n + m field at the timing when the polarity of the voltage at which the period of the input video signal and the period of the reverse voltage polarity of the input video signal are alternately inverted. Data is supplied. This corrected video data is obtained by multiplying the video data by a correction coefficient α. _2n × α, D _{2n + m} × α. The video data and the corrected video data shown in FIG. 3 are supplied to the liquid crystal panel 5, and a video is displayed.
[0041]
As described above, by using the corrected video data obtained by multiplying the video signal by the correction coefficient α, burn-in due to application of the DC voltage component for a long time is reduced, and luminance change due to superposition of the DC voltage component is reduced. As a result, flicker can be reduced. Further, according to the driving method of the liquid crystal display device of the present embodiment, it is possible to reduce flicker in a necessary area based on a video signal. In the above-described embodiment, an example has been described in which the image correction circuit 7 multiplies a video signal by a correction coefficient to generate corrected video data. However, instead of multiplying a video signal by a correction coefficient, a voltage to be applied to a pixel is used. Is multiplied by a correction coefficient, it is also possible to reduce flicker caused by superposition of a DC voltage component.
[0042]
(Embodiment 2)
FIG. 4 shows the liquid crystal characteristics of the luminance and the luminance change amount of the matrix type liquid crystal display device. In a liquid crystal display device, the liquid crystal characteristics of luminance and the amount of change in luminance are not linear. For example, as the luminance increases, the luminance change amount decreases. Therefore, when the correction coefficient α described in the first embodiment is applied to all luminances, luminances that cannot reduce flicker sufficiently occur from the actual liquid crystal characteristics of the liquid crystal display device and the luminance change amount.
[0043]
Therefore, in the present embodiment, a correction coefficient for each luminance is set from the liquid crystal characteristics of the luminance of the liquid crystal display device and the luminance change amount. In FIG. 4, the luminance change amount is Xa and the correction coefficient is 1-Xa in a region where the luminance is 0 to La. Next, in the region where the luminance is from La to Lb, the luminance change amount is set to Xb, and the correction coefficient is set to 1-Xb. Further, in the region where the luminance is from Lb to Lmax, the luminance change amount is Xc, and the correction coefficient is 1-Xc. As a result, an optimal correction coefficient suitable for the liquid crystal characteristics of the luminance and the luminance change amount is applied, and flicker can be sufficiently reduced.
[0044]
In FIG. 4, the luminance is divided into three regions (0 to La, La to Lb, and Lb to Lmax). However, in order to further obtain a correction coefficient corresponding to the liquid crystal characteristics of the luminance and the luminance change amount, Is divided into more areas, and a correction coefficient is set in each area.
[0045]
(Embodiment 3)
As described in the second embodiment, in order to make the correction coefficient more suitable for the liquid crystal characteristics of the luminance and the luminance change amount, the luminance is divided into more areas. In the case where the luminance is 64 gradations, if the luminance is divided into 64 and the correction coefficient is obtained, it is possible to perform the driving capable of reducing the flicker to which the optimal correction coefficient is applied to all luminance.
[0046]
In the present embodiment, based on the above idea, a look-up table is prepared in advance so that the correction coefficient can be referred to for each luminance, and the look-up table is stored in the memory of the image correction circuit 7. Using this look-up table, a correction coefficient for the corresponding luminance is applied to the video signal to generate corrected video data, thereby making it possible to reduce flicker.
[0047]
Accordingly, if the correction coefficient is obtained by dividing the luminance for each selectable gray scale, it is possible to perform the driving capable of reducing the flicker to which the optimum correction coefficient is applied to all the luminances. Note that it is also possible to create a look-up table only for gradations at a fixed interval, instead of creating a lookup table for every gradation.
[0048]
(Embodiment 4)
In the first embodiment, the correction coefficient is applied to the video signal to generate corrected video data. However, in the case of a liquid crystal display device for a specific use in which the displayed image is limited, the displayed image is Because of the simplicity, it is considered that sufficient flicker can be reduced without generating correction video data by obtaining a correction coefficient for each pixel.
[0049]
In the present embodiment, flicker is reduced by uniquely adding, to video data, a correction value for correcting flicker caused by luminance of a display image. This eliminates the need for a circuit that generates correction video data by applying the correction coefficient required in the first embodiment to the video signal, and can reduce sufficient flicker with a simple circuit configuration.
[0050]
Further, by changing the correction value for correcting flicker depending on the luminance of the display image, it is possible to sufficiently reduce flicker for display images of various luminances.
[0051]
【The invention's effect】
The liquid crystal display device according to claim 1, wherein the image belonging to a first field of a timing at which the period of the input video signal and the period of the reverse voltage polarity of the input video signal are inverted. The image signal control means for generating corrected image data to be supplied to the pixel by changing the signal reduces image burn-in due to application of a DC voltage component for a long time, and suppresses luminance change due to superposition of the DC voltage component. There is an effect that flicker can be reduced by reducing it.
[0052]
In the liquid crystal display device according to the second aspect of the present invention, the corrected video data is generated by multiplying the video signal by a predetermined coefficient, so that flicker of a necessary area can be reduced based on the video signal. effective.
[0053]
The liquid crystal display device according to claim 3 of the present invention changes a predetermined coefficient to be applied to the video signal according to the magnitude of the luminance of the video signal. Thus, there is an effect that flicker can be sufficiently reduced by applying various correction coefficients.
[0054]
In the liquid crystal display device according to the fourth aspect of the present invention, the corrected video data is generated by adding a predetermined value to the video signal. Therefore, there is an effect that sufficient flicker can be reduced with a simple circuit configuration.
[0055]
In the liquid crystal display device according to the fifth aspect of the present invention, a predetermined value added to the video signal is changed according to the magnitude of the luminance of the video signal. There is an effect that becomes possible.
[0056]
The liquid crystal display device according to claim 6 of the present invention generates the corrected video data corresponding to the video signal with reference to a predetermined look-up table. There is an effect that driving that can reduce the applied flicker can be performed.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a matrix type liquid crystal display device according to Embodiment 1 of the present invention.
FIG. 2 is a schematic diagram of a display of the matrix type liquid crystal display device according to Embodiment 1 of the present invention.
FIG. 3 is a timing chart of video data according to the first embodiment of the present invention.
FIG. 4 is a diagram illustrating a liquid crystal characteristic of a luminance and a luminance change amount of the matrix type liquid crystal display device according to the second embodiment of the present invention.
FIG. 5 is a schematic view of a display of a matrix type liquid crystal display device according to a conventional technique.
FIG. 6 is a schematic view of a display of a matrix type liquid crystal display device according to a conventional technique.
[Explanation of symbols]
1 liquid crystal display device, 2 basic circuit, 3 CPU, 4 timing generation circuit, 5
LCD panel, 6 AC drive control circuit, 7 Image correction circuit.

Claims (6)

Pixels are arranged in a matrix, a video signal input in the odd field and the even field is a different interlace driving liquid crystal display device,
Means for inverting the voltage polarity of the video signal input in the odd field and the even field,
Means for alternately inverting the period of the input video signal and the period of the reverse voltage polarity of the input video signal for each predetermined period longer than one field;
Correcting video data to be supplied to the pixel by changing the video signal belonging to the first field of the timing at which the period of the input video signal and the period of the reverse voltage polarity of the input video signal are inverted. A liquid crystal display device comprising: a video signal control unit that generates the video signal. The liquid crystal display device according to claim 1,
The liquid crystal display device, wherein the video signal control means generates the corrected video data by multiplying the video signal by a predetermined coefficient. The liquid crystal display device according to claim 2, wherein
2. The liquid crystal display device according to claim 1, wherein said video signal control means changes a predetermined coefficient to be applied to said video signal according to a magnitude of luminance of said video signal. The liquid crystal display device according to claim 1,
The liquid crystal display device, wherein the video signal control means generates the corrected video data by adding a predetermined value to the video signal. The liquid crystal display device according to claim 4, wherein
2. The liquid crystal display device according to claim 1, wherein said video signal control means changes a predetermined value added to said video signal in accordance with a magnitude of luminance of said video signal. The liquid crystal display device according to claim 1,
The liquid crystal display device, wherein the video signal control means generates the corrected video data corresponding to the video signal by referring to a predetermined look-up table.

Images